Prove the given reflection and transmission coefficients for oblique incidence.

Question

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Answer 1

Question

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

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Answer 2

Question

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

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Answer 3

Question

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

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Answer 4

Question

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

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Answer 5

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

Answer 6

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)

Simplify the expression.

τ⊥=2cos(θi)sin(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=2cos(θi)sin(θt)sin(θt+θi)

Conclusion:

Hence, the given reflection and transmission coefficients for oblique incidence are proved.

Answer 7

Chapter 10, Problem 73P

To determine

Prove the given reflection and transmission coefficients for oblique incidence.

Answer 8

Expert Solution & Answer

Explanation of Solution

Calculation:

Consider the expression of reflection coefficient in the parallel polarization of oblique incidence.

Γ∥=η2cos(θt)−η1cos(θi)η2cos(θt)+η1cos(θi) (1)

Here,

η1 is the intrinsic impedance of the medium-1,

η2 is the intrinsic impedance for medium-2,

θt is the angle of transmission, and

θi is the angle of incidence.

Consider the expression for intrinsic impedance for medium-1 (nonmagnetic medium).

η1=μoεoεr1

Consider the expression for intrinsic impedance for medium-2 (nonmagnetic medium).

η2=μoεoεr2

Substitute μoεoεr1 for η1 and μoεoεr2 for η2 in Equation (1).

Γ∥=μoεoεr2cos(θt)−μoεoεr1cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=1εr2cos(θt)−1εr1cos(θi)1εr2cos(θt)+1εr1cos(θi)=cos(θt)−εr2εr1cos(θi)cos(θt)+εr2εr1cos(θi)=cos(θt)−sin(θi)sin(θt)cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ∥=sin(θt)cos(θt)−sin(θi)cos(θi)sin(θt)cos(θt)+sin(θi)cos(θi)=2sin(θt)cos(θt)−2sin(θi)cos(θi)2sin(θt)cos(θt)+2sin(θi)cos(θi)=sin(2θt)−sin(2θi)sin(2θt)+sin(2θi)=sin(θt−θi)cos(θt+θi)sin(θt+θi)cos(θt−θi)

Simplify the expression.

Γ∥=[sin(θt−θi)cos(θt−θi)]{1[sin(θt+θi)cos(θt+θi)]}=tan(θt−θi)tan(θt+θi)

Consider the expression of transmission coefficient in the parallel polarization of oblique incidence.

τ∥=2η2cos(θi)η2cos(θt)+η1cos(θi)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ∥=2μoεoεr2cos(θi)μoεoεr2cos(θt)+μoεoεr1cos(θi)=21εr2cos(θi)1εr2cos(θt)+1εr1cos(θi)=2cos(θi)cos(θt)+εr2εr1cos(θi)=2cos(θi)cos(θt)+sin(θi)sin(θt)cos(θi)

Simplify the expression.

τ∥=2sin(θt)cos(θi)sin(θt)cos(θt)[sin2(θi)+cos2(θi)]+sin(θi)cos(θi)[sin2(θt)+cos2(θt)]=2sin(θt)cos(θi)[sin(θt)cos(θi)+sin(θi)cos(θt)][sin(θi)sin(θt)+cos(θi)cos(θt)]=2cos(θi)sin(θt)sin(θt+θi)cos(θt−θi)

Consider the expression of reflection coefficient in the perpendicular polarization of oblique incidence.

Γ⊥=η2cos(θi)−η1cos(θt)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

Γ⊥=μoεoεr2cos(θi)−μoεoεr1cos(θt)μoεoεr2cos(θi)+μoεoεr1cos(θt)=1εr2cos(θi)−1εr1cos(θt)1εr2cos(θi)+1εr1cos(θt)=cos(θi)−εr2εr1cos(θt)cos(θi)+εr2εr1cos(θt)=cos(θi)−sin(θi)sin(θt)cos(θt)cos(θi)+sin(θi)sin(θt)cos(θt) {∵εr2εr1=sin(θi)sin(θt)}

Simplify the expression.

Γ⊥=sin(θt)cos(θi)−sin(θi)cos(θt)sin(θt)cos(θi)+sin(θi)cos(θt)=sin(θt−θi)sin(θt+θi)

Consider the expression of transmission coefficient in the perpendicular polarization of oblique incidence.

τ⊥=2η2cos(θi)η2cos(θi)+η1cos(θt)

Substitute μoεoεr1 for η1 and μoεoεr2 for η2.

τ⊥=2μoεoεr2cos(θi)μoεoεr2cos(θi)+μoεoεr1cos(θt)=21εr2cos(θi)1εr2cos(θi)+1εr1cos(θt)=2cos(θi)cos(θi)+εr2εr1cos(θt)=2cos(θi)cos(θi)+sin(θi)sin(θt)cos(θt)